TW201445837A - Connector - Google Patents

Abstract

The present invention relates to a connector, which includes an input terminal, an optical splitting module, a number of output terminal, and an optical transmission module. The input terminal receives a first electrical signal from a first electrical device, and converts the first electrical signal into a first optical signal. The optical splitting module includes a first light receiver, a optical splitter, and a number of light emitter. The first light receiver receives the first optical signal. The optical splitter splits the first optical signal into a number of second optical signals same as each other. The light emitters emit the corresponding second optical signal. The output terminal converts the second optical signals into a number of second electrical signals, and transmits the second electrical signals to the second electrical device. The optical transmission module transmits the first optical signal to the first light receiver, and transmits the second optical signals to the corresponding input terminal.

Description

Connector

The present invention relates to connectors, and more particularly to a one-to-many connector.

The previous one-to-many connector (such as High-Definition Multimedia Interface, HDMI) includes an input terminal and a plurality of output terminals for electrically connecting a signal source to a plurality of display devices, thereby making the plural The display device is capable of displaying an image output by the signal source. However, the current one-to-many connectors are transmitted by copper wires. Since the distances of the plurality of output terminals are very close to each other, when a signal source with a high frequency is transmitted, the plurality of output terminals electromagnetically interfere with each other to make signals between each other. Crosstalk is generated to reduce the transmission quality of the signal.

In view of this, it is necessary to provide a connector that can effectively improve the quality of signal transmission.

A connector for implementing signal transmission between a first electronic device and a plurality of second electronic devices. The connector includes an input terminal, an optical branching module, a plurality of output terminals, and an optical transmission module. The input terminal is electrically connected to the first electronic device and configured to receive the first electrical signal of the first electronic device and convert the first electrical signal into a first optical signal. The optical branching module includes an optical splitter, a first optical receiver, and a plurality of first optical emitters. The first optical receiver is configured to receive the first optical signal. The optical splitter is configured to divide the first optical signal into two identical optical signals of a plurality of identical paths. The plurality of first light emitters are disposed corresponding to the plurality of second optical signals and configured to transmit the corresponding second optical signals. The plurality of output terminals are disposed corresponding to the plurality of first light emitters and configured to receive the corresponding second optical signal and convert the corresponding second optical signal into a second electrical signal, and further transmit the second electrical signal to the corresponding The second electronic device. The optical transmission module is configured to transmit the first optical signal to the first optical receiver and transmit the plurality of second optical signals to the corresponding output terminal.

Compared with the prior art, the connector of the present invention converts the first electrical signal into a first optical signal, and uses the optical branching module to divide the first optical signal into a plurality of second optical signals, and then transmits the optical signals by using the optical transmission module. The second optical signal of the plurality of roads. Since the optical signal does not generate electromagnetic interference during the transmission process or generates less electromagnetic interference than the electrical signal, crosstalk or crosstalk is not generated between the second optical signals of the plurality of signals, and the transmission quality of the signal is effectively improved.

100. . . Connector

201. . . First electronic device

202. . . Second electronic device

10. . . Input terminal

11. . . First electrical connector

13. . . Second light emitter

20. . . Optical branching module

twenty one. . . First light receiver

twenty two. . . Optical splitter

221. . . First fixed surface

222. . . Second fixed surface

twenty three. . . First light emitter

30. . . Output terminal

31. . . Second light receiver

33. . . Second electrical connector

40. . . Optical transmission module

41. . . First optical transmission component

411. . . First fiber

412. . . First optical coupling unit

413. . . Second optical coupling unit

413a. . . First accommodating slot

42. . . Second optical transmission element

421. . . Second fiber

422. . . Third optical coupling unit

422a. . . Second receiving slot

423. . . Fourth optical coupling unit

1 is a schematic structural view of a connector according to a preferred embodiment of the present invention.

The invention will be further described in detail below with reference to the accompanying drawings.

Referring to FIG. 1 , a connector 100 according to a preferred embodiment of the present invention is used to implement signal transmission between a first electronic device 201 and a plurality of second electronic devices 202 . The connector 100 includes an input terminal 10, an optical branching module 20, a plurality of output terminals 30, and an optical transmission module 40.

The input terminal 10 is configured to convert the first electrical signal of the first electronic device 201 (such as a signal source) into a first optical signal and transmit the first electrical signal to the optical branching module 20 .

The optical branching module 20 is configured to receive the first optical signal output by the input terminal 10, and divide the first optical signal into two identical optical signals of the same multiple paths. The optical branching module 20 includes a first optical receiver 21, an optical splitter 22, and a plurality of first optical transmitters 23. The first optical receiver 21 is configured to receive the first optical signal. The optical splitter 22 is configured to divide the first optical signal into the second optical signal whose multiple paths are identical. The plurality of first light emitters 23 are disposed corresponding to the plurality of second light signals for transmitting the corresponding second light signals. In the present embodiment, the optical splitter 22 includes a first fixed surface 221 and a second fixed surface 222 disposed opposite each other. The first light receiver 21 is disposed on the first fixing surface 221 , and the plurality of first light emitters 23 are disposed on the second fixing surface 222 . The optical splitter 22 can be a fused taper type optical splitter or a planar waveguide type optical splitter.

One end of the plurality of output terminals 30 is disposed in one-to-one correspondence with the plurality of first light emitters 23, and the other end is disposed in one-to-one correspondence with the plurality of second electronic devices 202 and is electrically connected. The multi-output terminal 30 is configured to receive the corresponding second optical signal, convert the corresponding second optical signal into a second electrical signal, and then transmit the second electrical signal to the corresponding second electronic device 202.

Specifically, the input terminal 10 includes a first electrical connector 11 and a second optical emitter 13. The first electrical connector 11 is electrically connected to the first electronic device 201 for receiving the electrical signal of the first electronic device 201. The second optical transmitter 13 is electrically connected to the first electrical connector 11 for converting the first electrical signal received by the first electrical connector 11 into the first optical signal, and transmitting the first optical signal. Signal.

Specifically, each output terminal 30 is electrically connected to one of the second electronic devices 202. Each of the output terminals 30 includes a second photoreceiver 31 and a second electrical connector 33. Each of the second optical receivers 31 is configured to receive a corresponding second optical signal and convert the corresponding second optical signal into a corresponding second electrical signal. The second electrical connector 33 is electrically connected to the second optical receiver for transmitting the corresponding second electrical signal to the corresponding second electronic device 202.

In this embodiment, the first light receiver 21 includes a solar panel or a photodiode, and the second light receiver 31 includes a solar panel or a photodiode, and the first light emitter 23 includes a laser diode. The body or the light emitting diode 13 includes a laser diode or a light emitting diode.

The optical transmission module 40 is configured to transmit the first optical signal to the optical branching module 20 and transmit the plurality of second optical signals to the corresponding output terminal 30. Specifically, the optical transmission module 40 includes a first optical transmission component 41 and a plurality of second optical transmission components 42.

The first optical transmission component 41 is configured to transmit the first optical signal to the optical branching module 20, and includes a first optical fiber 411, a first optical coupling portion 412, and a second optical coupling portion 413. The first optical fiber 411 is connected to the first optical coupling portion 412 and the second optical coupling portion 413 at opposite ends of the first optical fiber 411. The first light coupling portion 412 is detachably disposed on the input terminal 10 for ensuring that the first optical fiber 411 is aligned with the second light emitter 13 and ensures that the second light emitter 13 emits the first An optical signal can all enter the first optical fiber 411 to reduce the signal loss of the first optical signal. The second optical coupling portion 413 is detachably disposed on the optical branching module 20 for ensuring that the first optical fiber 411 is aligned with the first optical receiver 21 and ensures the exit from the first optical fiber 411. The first optical signal is all incident into the first optical receiver 21 to reduce the signal loss of the first optical signal.

The plurality of second light transmitting elements 42 are disposed corresponding to the plurality of first light emitters 23. Each of the second optical transmission elements 42 includes a second optical fiber 421, a third optical coupling portion 422, and a fourth optical coupling portion 423. The opposite ends of the second optical fiber 421 are connected to the third optical coupling portion 422 and the fourth optical coupling portion 423, respectively. The third optical coupling portion 422 is detachably disposed on the optical branching module 20 for ensuring that the second optical fiber 421 is aligned with the first optical transmitter 23 and ensures that the first optical transmitter 23 emits The second optical signal can all enter the second optical fiber 421. The fourth optical coupling portion 423 is detachably disposed on the output terminal 30 for ensuring that the second optical fiber 421 is aligned with the second optical receiver 31 and ensures the second optical signal emitted by the second optical fiber 421. All of them are incident into the second light receiver 31.

A first receiving groove 413a is defined in the second optical coupling portion 413. The first optical receiver 21 is received in the first receiving groove 413a. A second accommodating groove 422a is defined in the third light coupling portion 422. The first light emitter 23 is received in the second accommodating groove 422a.

Compared with the prior art, the connector of the present invention converts the first electrical signal into a first optical signal, and uses the optical branching module to divide the first optical signal into a plurality of second optical signals, and then transmits the optical signals by using the optical transmission module. The second optical signal of the plurality of roads. Since the optical signal does not generate electromagnetic interference during the transmission process or generates less electromagnetic interference than the electrical signal, crosstalk or crosstalk is not generated between the second optical signals of the plurality of signals, and the transmission quality of the signal is effectively improved.

In summary, the present invention has indeed met the requirements of the invention patent, and has filed a patent application according to law. However, the above description is only a preferred embodiment of the present invention, and it is not possible to limit the scope of the patent application of the present invention. Equivalent modifications or variations made by persons skilled in the art in light of the spirit of the invention are intended to be included within the scope of the following claims.

100. . . Connector

201. . . First electronic device

202. . . Second electronic device

10. . . Input terminal

11. . . First electrical connector

13. . . Second light emitter

20. . . Optical branching module

twenty one. . . First light receiver

twenty two. . . Optical splitter

221. . . First fixed surface

222. . . Second fixed surface

twenty three. . . First light emitter

30. . . Output terminal

31. . . Second light receiver

33. . . Second electrical connector

40. . . Optical transmission module

41. . . First optical transmission component

411. . . First fiber

412. . . First optical coupling unit

413. . . Second optical coupling unit

413a. . . First accommodating slot

42. . . Second optical transmission element

421. . . Second fiber

422. . . Third optical coupling unit

422a. . . Second receiving slot

423. . . Fourth optical coupling unit

Claims (9)

A connector for transmitting signal between a first electronic device and a plurality of second electronic devices, the connector comprising an input terminal, an optical branching module, a plurality of output terminals, and an optical transmission module, the input The terminal is electrically connected to the first electronic device and configured to receive the first electrical signal of the first electronic device and convert the first electrical signal into a first optical signal; the optical branching module includes an optical splitter and a a first optical receiver and a plurality of first optical transmitters; the first optical receiver is configured to receive the first optical signal, and the optical splitter is configured to divide the first optical signal into two identical optical signals that are identical in a plurality of paths; The plurality of first light emitters are disposed corresponding to the plurality of second optical signals and configured to transmit the corresponding second optical signals; the plurality of output terminals are disposed corresponding to the plurality of first light emitters and configured to receive the corresponding second light Converting the corresponding second optical signal into a second electrical signal, and transmitting the second electrical signal to the corresponding second electronic device; the optical transmission module is configured to transmit the first optical signal to the second electronic device A plurality of light receiver and the second optical signal transmission path to the corresponding output terminal. The connector of claim 1, wherein the input terminal comprises a first electrical connector and a second optical connector, the first electrical connector being electrically connected to the first electronic device and configured to receive the first The second optical transmitter is configured to convert the first electrical signal into the first optical signal and transmit the first optical signal. The connector of claim 2, wherein the plurality of output terminals are disposed in one-to-one correspondence with the plurality of first light emitters, each of the output terminals comprising a second light receiver and a second electrical connector. The second optical receiver is configured to receive the second optical signal emitted by the corresponding first optical transmitter and convert the corresponding second optical signal into the corresponding second electrical signal; the second electrical connector and the second optical connector The second optical receiver is electrically connected to transmit the corresponding second electrical signal to the corresponding second electronic device. The connector of claim 3, wherein the first light receiver comprises a solar panel or a photodiode, the second light receiver comprising a solar panel or a photodiode, the first light emitter comprising a thunder A diode or a light emitting diode is included, and the second light emitter comprises a laser diode or a light emitting diode. The connector of claim 3, wherein the optical transmission module includes a first optical transmission component, the first optical transmission component is configured to transmit the first optical signal to the first optical receiver and includes a first An optical fiber, a first optical coupling portion and a second optical coupling portion, wherein the opposite ends of the first optical fiber are respectively connected to the first optical coupling portion and the second optical coupling portion; the first optical coupling portion is detachable Is disposed on the input terminal and configured to ensure that the first optical fiber is aligned with the second optical transmitter, and that the first optical signal emitted by the second optical transmitter can enter the first optical fiber; The second optical coupling portion is detachably disposed on the first optical receiver, configured to ensure that the first optical fiber is aligned with the first optical receiver, and ensure that the first optical signal emitted from the first optical fiber is all shot Into the first optical receiver. The connector of claim 5, wherein the optical transmission module comprises a plurality of second optical transmission components, the plurality of second optical transmission components being disposed corresponding to the plurality of first optical transmitters, each of the second optical transmission components a second optical fiber, a third optical coupling portion, and a fourth optical coupling portion, wherein the opposite ends of the second optical fiber are respectively connected to the third optical coupling portion and the fourth optical coupling portion; the third optical coupling Removably disposed on the first light emitter and configured to ensure that the second optical fiber is aligned with the first light emitter, and that the second light signal emitted by the first light emitter can enter the first The second optical coupling portion is detachably disposed on the output terminal for ensuring alignment of the second optical fiber with the second optical receiver, and ensuring that the second optical signal emitted by the second optical fiber is all Injection into the second light receiver. The connector of claim 6, wherein the second optical coupling portion has a first receiving slot, the first optical receiver is received in the first receiving slot; and the second optical coupling portion is provided with a second The first light emitter is received in the second receiving groove. The connector of claim 1, wherein the optical splitter comprises a first fixed surface and a second fixed surface disposed opposite to each other, and the first optical receiver is disposed on the first fixed surface, the plurality of A light emitter is disposed on the second fixed surface. The connector of claim 1, wherein the optical splitter is a fused taper type optical splitter or a planar waveguide type optical splitter.